/* * This file is part of the render object implementation for KHTML. * * Copyright (C) 1999 Lars Knoll (knoll@kde.org) * (C) 1999 Antti Koivisto (koivisto@kde.org) * Copyright (C) 2003 Apple Computer, Inc. * * This library is free software; you can redistribute it and/or * modify it under the terms of the GNU Library General Public * License as published by the Free Software Foundation; either * version 2 of the License, or (at your option) any later version. * * This library is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU * Library General Public License for more details. * * You should have received a copy of the GNU Library General Public License * along with this library; see the file COPYING.LIB. If not, write to * the Free Software Foundation, Inc., 59 Temple Place - Suite 330, * Boston, MA 02111-1307, USA. * */ #include "config.h" #include "RenderFlexibleBox.h" #include "CharacterNames.h" #include "RenderLayer.h" #include "RenderView.h" using namespace std; namespace WebCore { class FlexBoxIterator { public: FlexBoxIterator(RenderFlexibleBox* parent) { box = parent; if (box->style()->boxOrient() == HORIZONTAL && box->style()->direction() == RTL) forward = box->style()->boxDirection() != BNORMAL; else forward = box->style()->boxDirection() == BNORMAL; lastOrdinal = 1; if (!forward) { // No choice, since we're going backwards, we have to find out the highest ordinal up front. RenderObject* child = box->firstChild(); while (child) { if (child->style()->boxOrdinalGroup() > lastOrdinal) lastOrdinal = child->style()->boxOrdinalGroup(); child = child->nextSibling(); } } reset(); } void reset() { current = 0; currentOrdinal = forward ? 0 : lastOrdinal+1; } RenderObject* first() { reset(); return next(); } RenderObject* next() { do { if (!current) { if (forward) { currentOrdinal++; if (currentOrdinal > lastOrdinal) return 0; current = box->firstChild(); } else { currentOrdinal--; if (currentOrdinal == 0) return 0; current = box->lastChild(); } } else current = forward ? current->nextSibling() : current->previousSibling(); if (current && current->style()->boxOrdinalGroup() > lastOrdinal) lastOrdinal = current->style()->boxOrdinalGroup(); } while (!current || current->style()->boxOrdinalGroup() != currentOrdinal || current->style()->visibility() == COLLAPSE); return current; } private: RenderFlexibleBox* box; RenderObject* current; bool forward; unsigned int currentOrdinal; unsigned int lastOrdinal; }; RenderFlexibleBox::RenderFlexibleBox(Node* node) :RenderBlock(node) { setChildrenInline(false); // All of our children must be block-level m_flexingChildren = m_stretchingChildren = false; } RenderFlexibleBox::~RenderFlexibleBox() { } void RenderFlexibleBox::calcHorizontalPrefWidths() { RenderObject *child = firstChild(); while (child) { // positioned children don't affect the minmaxwidth if (child->isPositioned() || child->style()->visibility() == COLLAPSE) { child = child->nextSibling(); continue; } // A margin basically has three types: fixed, percentage, and auto (variable). // Auto and percentage margins simply become 0 when computing min/max width. // Fixed margins can be added in as is. Length ml = child->style()->marginLeft(); Length mr = child->style()->marginRight(); int margin = 0, marginLeft = 0, marginRight = 0; if (ml.isFixed()) marginLeft += ml.value(); if (mr.isFixed()) marginRight += mr.value(); margin = marginLeft + marginRight; m_minPrefWidth += child->minPrefWidth() + margin; m_maxPrefWidth += child->maxPrefWidth() + margin; child = child->nextSibling(); } } void RenderFlexibleBox::calcVerticalPrefWidths() { RenderObject *child = firstChild(); while(child != 0) { // Positioned children and collapsed children don't affect the min/max width if (child->isPositioned() || child->style()->visibility() == COLLAPSE) { child = child->nextSibling(); continue; } // A margin basically has three types: fixed, percentage, and auto (variable). // Auto/percentage margins simply become 0 when computing min/max width. // Fixed margins can be added in as is. Length ml = child->style()->marginLeft(); Length mr = child->style()->marginRight(); int margin = 0; if (ml.isFixed()) margin += ml.value(); if (mr.isFixed()) margin += mr.value(); int w = child->minPrefWidth() + margin; m_minPrefWidth = max(w, m_minPrefWidth); w = child->maxPrefWidth() + margin; m_maxPrefWidth = max(w, m_maxPrefWidth); child = child->nextSibling(); } } void RenderFlexibleBox::calcPrefWidths() { ASSERT(prefWidthsDirty()); if (style()->width().isFixed() && style()->width().value() > 0) m_minPrefWidth = m_maxPrefWidth = calcContentBoxWidth(style()->width().value()); else { m_minPrefWidth = m_maxPrefWidth = 0; if (hasMultipleLines() || isVertical()) calcVerticalPrefWidths(); else calcHorizontalPrefWidths(); m_maxPrefWidth = max(m_minPrefWidth, m_maxPrefWidth); } if (style()->minWidth().isFixed() && style()->minWidth().value() > 0) { m_maxPrefWidth = max(m_maxPrefWidth, calcContentBoxWidth(style()->minWidth().value())); m_minPrefWidth = max(m_minPrefWidth, calcContentBoxWidth(style()->minWidth().value())); } if (style()->maxWidth().isFixed() && style()->maxWidth().value() != undefinedLength) { m_maxPrefWidth = min(m_maxPrefWidth, calcContentBoxWidth(style()->maxWidth().value())); m_minPrefWidth = min(m_minPrefWidth, calcContentBoxWidth(style()->maxWidth().value())); } int toAdd = borderLeft() + borderRight() + paddingLeft() + paddingRight(); m_minPrefWidth += toAdd; m_maxPrefWidth += toAdd; setPrefWidthsDirty(false); } void RenderFlexibleBox::layoutBlock(bool relayoutChildren) { ASSERT(needsLayout()); if (!relayoutChildren && layoutOnlyPositionedObjects()) return; IntRect oldBounds; IntRect oldOutlineBox; bool checkForRepaint = checkForRepaintDuringLayout(); if (checkForRepaint) { oldBounds = absoluteClippedOverflowRect(); oldOutlineBox = absoluteOutlineBox(); } view()->pushLayoutState(this, IntSize(m_x, m_y)); int previousWidth = m_width; int previousHeight = m_height; calcWidth(); calcHeight(); m_overflowWidth = m_width; if (previousWidth != m_width || previousHeight != m_height || (parent()->isFlexibleBox() && parent()->style()->boxOrient() == HORIZONTAL && parent()->style()->boxAlign() == BSTRETCH)) relayoutChildren = true; m_height = 0; m_overflowHeight = 0; m_flexingChildren = m_stretchingChildren = false; initMaxMarginValues(); // For overflow:scroll blocks, ensure we have both scrollbars in place always. if (scrollsOverflow()) { if (style()->overflowX() == OSCROLL) m_layer->setHasHorizontalScrollbar(true); if (style()->overflowY() == OSCROLL) m_layer->setHasVerticalScrollbar(true); } if (isHorizontal()) layoutHorizontalBox(relayoutChildren); else layoutVerticalBox(relayoutChildren); int oldHeight = m_height; calcHeight(); if (oldHeight != m_height) { // If the block got expanded in size, then increase our overflowheight to match. if (m_overflowHeight > m_height) m_overflowHeight -= (borderBottom() + paddingBottom() + horizontalScrollbarHeight()); if (m_overflowHeight < m_height) m_overflowHeight = m_height; } if (previousHeight != m_height) relayoutChildren = true; layoutPositionedObjects(relayoutChildren || isRoot()); if (!isFloatingOrPositioned() && m_height == 0) { // We are a block with no border and padding and a computed height // of 0. The CSS spec states that zero-height blocks collapse their margins // together. // When blocks are self-collapsing, we just use the top margin values and set the // bottom margin max values to 0. This way we don't factor in the values // twice when we collapse with our previous vertically adjacent and // following vertically adjacent blocks. int pos = maxTopPosMargin(); int neg = maxTopNegMargin(); if (maxBottomPosMargin() > pos) pos = maxBottomPosMargin(); if (maxBottomNegMargin() > neg) neg = maxBottomNegMargin(); setMaxTopMargins(pos, neg); setMaxBottomMargins(0, 0); } // Always ensure our overflow width is at least as large as our width. if (m_overflowWidth < m_width) m_overflowWidth = m_width; if (!hasOverflowClip()) { if (ShadowData* boxShadow = style()->boxShadow()) { m_overflowLeft = min(m_overflowLeft, boxShadow->x - boxShadow->blur); m_overflowWidth = max(m_overflowWidth, m_width + boxShadow->x + boxShadow->blur); m_overflowTop = min(m_overflowTop, boxShadow->y - boxShadow->blur); m_overflowHeight = max(m_overflowHeight, m_height + boxShadow->y + boxShadow->blur); } } view()->popLayoutState(); // Update our scrollbars if we're overflow:auto/scroll/hidden now that we know if // we overflow or not. if (hasOverflowClip()) m_layer->updateScrollInfoAfterLayout(); // Repaint with our new bounds if they are different from our old bounds. if (checkForRepaint) repaintAfterLayoutIfNeeded(oldBounds, oldOutlineBox); setNeedsLayout(false); } void RenderFlexibleBox::layoutHorizontalBox(bool relayoutChildren) { int toAdd = borderBottom() + paddingBottom() + horizontalScrollbarHeight(); int yPos = borderTop() + paddingTop(); int xPos = borderLeft() + paddingLeft(); bool heightSpecified = false; int oldHeight = 0; unsigned int highestFlexGroup = 0; unsigned int lowestFlexGroup = 0; bool haveFlex = false; int remainingSpace = 0; m_overflowHeight = m_height; // The first walk over our kids is to find out if we have any flexible children. FlexBoxIterator iterator(this); RenderObject* child = iterator.next(); while (child) { // Check to see if this child flexes. if (!child->isPositioned() && child->style()->boxFlex() > 0.0f) { // We always have to lay out flexible objects again, since the flex distribution // may have changed, and we need to reallocate space. child->setOverrideSize(-1); if (!relayoutChildren) child->setChildNeedsLayout(true, false); haveFlex = true; unsigned int flexGroup = child->style()->boxFlexGroup(); if (lowestFlexGroup == 0) lowestFlexGroup = flexGroup; if (flexGroup < lowestFlexGroup) lowestFlexGroup = flexGroup; if (flexGroup > highestFlexGroup) highestFlexGroup = flexGroup; } child = iterator.next(); } // We do 2 passes. The first pass is simply to lay everyone out at // their preferred widths. The second pass handles flexing the children. do { // Reset our height. m_height = yPos; m_overflowHeight = m_height; xPos = borderLeft() + paddingLeft(); // Our first pass is done without flexing. We simply lay the children // out within the box. We have to do a layout first in order to determine // our box's intrinsic height. int maxAscent = 0, maxDescent = 0; child = iterator.first(); while (child) { // make sure we relayout children if we need it. if (relayoutChildren || (child->isReplaced() && (child->style()->width().isPercent() || child->style()->height().isPercent()))) child->setChildNeedsLayout(true, false); if (child->isPositioned()) { child = iterator.next(); continue; } // Compute the child's vertical margins. child->calcVerticalMargins(); // Now do the layout. child->layoutIfNeeded(); // Update our height and overflow height. if (style()->boxAlign() == BBASELINE) { int ascent = child->marginTop() + child->getBaselineOfFirstLineBox(); if (ascent == -1) ascent = child->marginTop() + child->height() + child->marginBottom(); int descent = (child->marginTop() + child->height() + child->marginBottom()) - ascent; // Update our maximum ascent. maxAscent = max(maxAscent, ascent); // Update our maximum descent. maxDescent = max(maxDescent, descent); // Now update our height. m_height = max(yPos + maxAscent + maxDescent, m_height); } else m_height = max(m_height, yPos + child->marginTop() + child->height() + child->marginBottom()); child = iterator.next(); } if (!iterator.first() && hasLineIfEmpty()) m_height += lineHeight(true, true); m_height += toAdd; // Always make sure our overflowheight is at least our height. if (m_overflowHeight < m_height) m_overflowHeight = m_height; oldHeight = m_height; calcHeight(); relayoutChildren = false; if (oldHeight != m_height) heightSpecified = true; // Now that our height is actually known, we can place our boxes. m_stretchingChildren = (style()->boxAlign() == BSTRETCH); child = iterator.first(); while (child) { if (child->isPositioned()) { child->containingBlock()->insertPositionedObject(child); if (child->hasStaticX()) { if (style()->direction() == LTR) child->setStaticX(xPos); else child->setStaticX(width() - xPos); } if (child->hasStaticY()) child->setStaticY(yPos); child = iterator.next(); continue; } // We need to see if this child's height has changed, since we make block elements // fill the height of a containing box by default. // Now do a layout. int oldChildHeight = child->height(); static_cast(child)->calcHeight(); if (oldChildHeight != child->height()) child->setChildNeedsLayout(true, false); child->layoutIfNeeded(); // We can place the child now, using our value of box-align. xPos += child->marginLeft(); int childY = yPos; switch (style()->boxAlign()) { case BCENTER: childY += child->marginTop() + max(0, (contentHeight() - (child->height() + child->marginTop() + child->marginBottom()))/2); break; case BBASELINE: { int ascent = child->marginTop() + child->getBaselineOfFirstLineBox(); if (ascent == -1) ascent = child->marginTop() + child->height() + child->marginBottom(); childY += child->marginTop() + (maxAscent - ascent); break; } case BEND: childY += contentHeight() - child->marginBottom() - child->height(); break; default: // BSTART childY += child->marginTop(); break; } placeChild(child, xPos, childY); if (child->isRenderBlock()) static_cast(child)->addVisualOverflow(static_cast(child)->floatRect()); m_overflowHeight = max(m_overflowHeight, childY + child->overflowHeight(false)); m_overflowTop = min(m_overflowTop, child->yPos() + child->overflowTop(false)); xPos += child->width() + child->marginRight(); child = iterator.next(); } remainingSpace = borderLeft() + paddingLeft() + contentWidth() - xPos; m_stretchingChildren = false; if (m_flexingChildren) haveFlex = false; // We're done. else if (haveFlex) { // We have some flexible objects. See if we need to grow/shrink them at all. if (!remainingSpace) break; // Allocate the remaining space among the flexible objects. If we are trying to // grow, then we go from the lowest flex group to the highest flex group. For shrinking, // we go from the highest flex group to the lowest group. bool expanding = remainingSpace > 0; unsigned int start = expanding ? lowestFlexGroup : highestFlexGroup; unsigned int end = expanding? highestFlexGroup : lowestFlexGroup; for (unsigned int i = start; i <= end && remainingSpace; i++) { // Always start off by assuming the group can get all the remaining space. int groupRemainingSpace = remainingSpace; do { // Flexing consists of multiple passes, since we have to change ratios every time an object hits its max/min-width // For a given pass, we always start off by computing the totalFlex of all objects that can grow/shrink at all, and // computing the allowed growth before an object hits its min/max width (and thus // forces a totalFlex recomputation). int groupRemainingSpaceAtBeginning = groupRemainingSpace; float totalFlex = 0.0f; child = iterator.first(); while (child) { if (allowedChildFlex(child, expanding, i)) totalFlex += child->style()->boxFlex(); child = iterator.next(); } child = iterator.first(); int spaceAvailableThisPass = groupRemainingSpace; while (child) { int allowedFlex = allowedChildFlex(child, expanding, i); if (allowedFlex) { int projectedFlex = (allowedFlex == INT_MAX) ? allowedFlex : (int)(allowedFlex * (totalFlex / child->style()->boxFlex())); spaceAvailableThisPass = expanding ? min(spaceAvailableThisPass, projectedFlex) : max(spaceAvailableThisPass, projectedFlex); } child = iterator.next(); } // The flex groups may not have any flexible objects this time around. if (!spaceAvailableThisPass || totalFlex == 0.0f) { // If we just couldn't grow/shrink any more, then it's time to transition to the next flex group. groupRemainingSpace = 0; continue; } // Now distribute the space to objects. child = iterator.first(); while (child && spaceAvailableThisPass && totalFlex) { if (allowedChildFlex(child, expanding, i)) { int spaceAdd = (int)(spaceAvailableThisPass * (child->style()->boxFlex()/totalFlex)); if (spaceAdd) { child->setOverrideSize(child->overrideWidth() + spaceAdd); m_flexingChildren = true; relayoutChildren = true; } spaceAvailableThisPass -= spaceAdd; remainingSpace -= spaceAdd; groupRemainingSpace -= spaceAdd; totalFlex -= child->style()->boxFlex(); } child = iterator.next(); } if (groupRemainingSpace == groupRemainingSpaceAtBeginning) { // this is not advancing, avoid getting stuck by distributing the remaining pixels child = iterator.first(); int spaceAdd = groupRemainingSpace > 0 ? 1 : -1; while (child && groupRemainingSpace) { if (allowedChildFlex(child, expanding, i)) { child->setOverrideSize(child->overrideWidth() + spaceAdd); m_flexingChildren = true; relayoutChildren = true; remainingSpace -= spaceAdd; groupRemainingSpace -= spaceAdd; } child = iterator.next(); } } } while (groupRemainingSpace); } // We didn't find any children that could grow. if (haveFlex && !m_flexingChildren) haveFlex = false; } } while (haveFlex); m_flexingChildren = false; if (remainingSpace > 0 && ((style()->direction() == LTR && style()->boxPack() != BSTART) || (style()->direction() == RTL && style()->boxPack() != BEND))) { // Children must be repositioned. int offset = 0; if (style()->boxPack() == BJUSTIFY) { // Determine the total number of children. int totalChildren = 0; child = iterator.first(); while (child) { if (child->isPositioned()) { child = iterator.next(); continue; } totalChildren++; child = iterator.next(); } // Iterate over the children and space them out according to the // justification level. if (totalChildren > 1) { totalChildren--; bool firstChild = true; child = iterator.first(); while (child) { if (child->isPositioned()) { child = iterator.next(); continue; } if (firstChild) { firstChild = false; child = iterator.next(); continue; } offset += remainingSpace/totalChildren; remainingSpace -= (remainingSpace/totalChildren); totalChildren--; placeChild(child, child->xPos()+offset, child->yPos()); child = iterator.next(); } } } else { if (style()->boxPack() == BCENTER) offset += remainingSpace/2; else // END for LTR, START for RTL offset += remainingSpace; child = iterator.first(); while (child) { if (child->isPositioned()) { child = iterator.next(); continue; } placeChild(child, child->xPos()+offset, child->yPos()); child = iterator.next(); } } } child = iterator.first(); while (child && child->isPositioned()) { child = iterator.next(); } if (child) { m_overflowLeft = min(child->xPos() + child->overflowLeft(false), m_overflowLeft); RenderObject* lastChild = child; while ((child = iterator.next())) { if (!child->isPositioned()) lastChild = child; } m_overflowWidth = max(lastChild->xPos() + lastChild->overflowWidth(false), m_overflowWidth); } // So that the calcHeight in layoutBlock() knows to relayout positioned objects because of // a height change, we revert our height back to the intrinsic height before returning. if (heightSpecified) m_height = oldHeight; } void RenderFlexibleBox::layoutVerticalBox(bool relayoutChildren) { int xPos = borderLeft() + paddingLeft(); int yPos = borderTop() + paddingTop(); if( style()->direction() == RTL ) xPos = m_width - paddingRight() - borderRight(); int toAdd = borderBottom() + paddingBottom() + horizontalScrollbarHeight(); bool heightSpecified = false; int oldHeight = 0; unsigned int highestFlexGroup = 0; unsigned int lowestFlexGroup = 0; bool haveFlex = false; int remainingSpace = 0; // The first walk over our kids is to find out if we have any flexible children. FlexBoxIterator iterator(this); RenderObject *child = iterator.next(); while (child) { // Check to see if this child flexes. if (!child->isPositioned() && child->style()->boxFlex() > 0.0f) { // We always have to lay out flexible objects again, since the flex distribution // may have changed, and we need to reallocate space. child->setOverrideSize(-1); if (!relayoutChildren) child->setChildNeedsLayout(true, false); haveFlex = true; unsigned int flexGroup = child->style()->boxFlexGroup(); if (lowestFlexGroup == 0) lowestFlexGroup = flexGroup; if (flexGroup < lowestFlexGroup) lowestFlexGroup = flexGroup; if (flexGroup > highestFlexGroup) highestFlexGroup = flexGroup; } child = iterator.next(); } // We confine the line clamp ugliness to vertical flexible boxes (thus keeping it out of // mainstream block layout); this is not really part of the XUL box model. bool haveLineClamp = style()->lineClamp() >= 0 && style()->lineClamp() <= 100; if (haveLineClamp) { int maxLineCount = 0; child = iterator.first(); while (child) { if (!child->isPositioned()) { if (relayoutChildren || (child->isReplaced() && (child->style()->width().isPercent() || child->style()->height().isPercent())) || (child->style()->height().isAuto() && child->isBlockFlow() && !child->needsLayout())) { child->setChildNeedsLayout(true, false); // Dirty all the positioned objects. if (child->isRenderBlock()) { static_cast(child)->markPositionedObjectsForLayout(); static_cast(child)->clearTruncation(); } } child->layoutIfNeeded(); if (child->style()->height().isAuto() && child->isBlockFlow()) maxLineCount = max(maxLineCount, static_cast(child)->lineCount()); } child = iterator.next(); } // Get the # of lines and then alter all block flow children with auto height to use the // specified height. int numVisibleLines = int((maxLineCount+1)*style()->lineClamp()/100.0); if (numVisibleLines < maxLineCount) { for (child = iterator.first(); child; child = iterator.next()) { if (child->isPositioned() || !child->style()->height().isAuto() || !child->isBlockFlow()) continue; RenderBlock* blockChild = static_cast(child); int lineCount = blockChild->lineCount(); if (lineCount <= numVisibleLines) continue; int newHeight = blockChild->heightForLineCount(numVisibleLines); if (newHeight == child->height()) continue; child->setChildNeedsLayout(true, false); child->setOverrideSize(newHeight); m_flexingChildren = true; child->layoutIfNeeded(); m_flexingChildren = false; child->setOverrideSize(-1); // FIXME: For now don't support RTL. if (style()->direction() != LTR) continue; // Get the last line RootInlineBox* lastLine = blockChild->lineAtIndex(lineCount-1); if (!lastLine) continue; // See if the last item is an anchor InlineBox* anchorBox = lastLine->lastChild(); if (!anchorBox) continue; if (!anchorBox->object()->element()) continue; if (!anchorBox->object()->element()->isLink()) continue; RootInlineBox* lastVisibleLine = blockChild->lineAtIndex(numVisibleLines-1); if (!lastVisibleLine) continue; const UChar ellipsisAndSpace[2] = { horizontalEllipsis, ' ' }; static AtomicString ellipsisAndSpaceStr(ellipsisAndSpace, 2); const Font& font = style(numVisibleLines == 1)->font(); int ellipsisAndSpaceWidth = font.width(TextRun(ellipsisAndSpace, 2)); // Get ellipsis width + " " + anchor width int totalWidth = ellipsisAndSpaceWidth + anchorBox->width(); // See if this width can be accommodated on the last visible line RenderBlock* destBlock = static_cast(lastVisibleLine->object()); RenderBlock* srcBlock = static_cast(lastLine->object()); // FIXME: Directions of src/destBlock could be different from our direction and from one another. if (srcBlock->style()->direction() != LTR) continue; if (destBlock->style()->direction() != LTR) continue; int blockEdge = destBlock->rightOffset(lastVisibleLine->yPos()); if (!lastVisibleLine->canAccommodateEllipsis(true, blockEdge, lastVisibleLine->xPos() + lastVisibleLine->width(), totalWidth)) continue; // Let the truncation code kick in. lastVisibleLine->placeEllipsis(ellipsisAndSpaceStr, true, blockEdge, totalWidth, anchorBox); destBlock->setHasMarkupTruncation(true); } } } // We do 2 passes. The first pass is simply to lay everyone out at // their preferred widths. The second pass handles flexing the children. // Our first pass is done without flexing. We simply lay the children // out within the box. do { m_height = borderTop() + paddingTop(); int minHeight = m_height + toAdd; m_overflowHeight = m_height; child = iterator.first(); while (child) { // make sure we relayout children if we need it. if (!haveLineClamp && (relayoutChildren || (child->isReplaced() && (child->style()->width().isPercent() || child->style()->height().isPercent())))) child->setChildNeedsLayout(true, false); if (child->isPositioned()) { child->containingBlock()->insertPositionedObject(child); if (child->hasStaticX()) { if (style()->direction() == LTR) child->setStaticX(borderLeft()+paddingLeft()); else child->setStaticX(borderRight()+paddingRight()); } if (child->hasStaticY()) child->setStaticY(m_height); child = iterator.next(); continue; } // Compute the child's vertical margins. child->calcVerticalMargins(); // Add in the child's marginTop to our height. m_height += child->marginTop(); // Now do a layout. child->layoutIfNeeded(); // We can place the child now, using our value of box-align. int childX = borderLeft() + paddingLeft(); switch (style()->boxAlign()) { case BCENTER: case BBASELINE: // Baseline just maps to center for vertical boxes childX += child->marginLeft() + max(0, (contentWidth() - (child->width() + child->marginLeft() + child->marginRight()))/2); break; case BEND: if (style()->direction() == RTL) childX += child->marginLeft(); else childX += contentWidth() - child->marginRight() - child->width(); break; default: // BSTART/BSTRETCH if (style()->direction() == LTR) childX += child->marginLeft(); else childX += contentWidth() - child->marginRight() - child->width(); break; } // Place the child. placeChild(child, childX, m_height); m_height += child->height() + child->marginBottom(); if (child->isRenderBlock()) static_cast(child)->addVisualOverflow(static_cast(child)->floatRect()); // See if this child has made our overflow need to grow. m_overflowWidth = max(child->xPos() + child->overflowWidth(false), m_overflowWidth); m_overflowLeft = min(child->xPos() + child->overflowLeft(false), m_overflowLeft); child = iterator.next(); } yPos = m_height; if (!iterator.first() && hasLineIfEmpty()) m_height += lineHeight(true, true); m_height += toAdd; // Negative margins can cause our height to shrink below our minimal height (border/padding). // If this happens, ensure that the computed height is increased to the minimal height. if (m_height < minHeight) m_height = minHeight; // Always make sure our overflowheight is at least our height. if (m_overflowHeight < m_height) m_overflowHeight = m_height; // Now we have to calc our height, so we know how much space we have remaining. oldHeight = m_height; calcHeight(); if (oldHeight != m_height) heightSpecified = true; remainingSpace = borderTop() + paddingTop() + contentHeight() - yPos; if (m_flexingChildren) haveFlex = false; // We're done. else if (haveFlex) { // We have some flexible objects. See if we need to grow/shrink them at all. if (!remainingSpace) break; // Allocate the remaining space among the flexible objects. If we are trying to // grow, then we go from the lowest flex group to the highest flex group. For shrinking, // we go from the highest flex group to the lowest group. bool expanding = remainingSpace > 0; unsigned int start = expanding ? lowestFlexGroup : highestFlexGroup; unsigned int end = expanding? highestFlexGroup : lowestFlexGroup; for (unsigned int i = start; i <= end && remainingSpace; i++) { // Always start off by assuming the group can get all the remaining space. int groupRemainingSpace = remainingSpace; do { // Flexing consists of multiple passes, since we have to change ratios every time an object hits its max/min-width // For a given pass, we always start off by computing the totalFlex of all objects that can grow/shrink at all, and // computing the allowed growth before an object hits its min/max width (and thus // forces a totalFlex recomputation). int groupRemainingSpaceAtBeginning = groupRemainingSpace; float totalFlex = 0.0f; child = iterator.first(); while (child) { if (allowedChildFlex(child, expanding, i)) totalFlex += child->style()->boxFlex(); child = iterator.next(); } child = iterator.first(); int spaceAvailableThisPass = groupRemainingSpace; while (child) { int allowedFlex = allowedChildFlex(child, expanding, i); if (allowedFlex) { int projectedFlex = (allowedFlex == INT_MAX) ? allowedFlex : (int)(allowedFlex * (totalFlex / child->style()->boxFlex())); spaceAvailableThisPass = expanding ? min(spaceAvailableThisPass, projectedFlex) : max(spaceAvailableThisPass, projectedFlex); } child = iterator.next(); } // The flex groups may not have any flexible objects this time around. if (!spaceAvailableThisPass || totalFlex == 0.0f) { // If we just couldn't grow/shrink any more, then it's time to transition to the next flex group. groupRemainingSpace = 0; continue; } // Now distribute the space to objects. child = iterator.first(); while (child && spaceAvailableThisPass && totalFlex) { if (allowedChildFlex(child, expanding, i)) { int spaceAdd = (int)(spaceAvailableThisPass * (child->style()->boxFlex()/totalFlex)); if (spaceAdd) { child->setOverrideSize(child->overrideHeight() + spaceAdd); m_flexingChildren = true; relayoutChildren = true; } spaceAvailableThisPass -= spaceAdd; remainingSpace -= spaceAdd; groupRemainingSpace -= spaceAdd; totalFlex -= child->style()->boxFlex(); } child = iterator.next(); } if (groupRemainingSpace == groupRemainingSpaceAtBeginning) { // this is not advancing, avoid getting stuck by distributing the remaining pixels child = iterator.first(); int spaceAdd = groupRemainingSpace > 0 ? 1 : -1; while (child && groupRemainingSpace) { if (allowedChildFlex(child, expanding, i)) { child->setOverrideSize(child->overrideHeight() + spaceAdd); m_flexingChildren = true; relayoutChildren = true; remainingSpace -= spaceAdd; groupRemainingSpace -= spaceAdd; } child = iterator.next(); } } } while (groupRemainingSpace); } // We didn't find any children that could grow. if (haveFlex && !m_flexingChildren) haveFlex = false; } } while (haveFlex); if (style()->boxPack() != BSTART && remainingSpace > 0) { // Children must be repositioned. int offset = 0; if (style()->boxPack() == BJUSTIFY) { // Determine the total number of children. int totalChildren = 0; child = iterator.first(); while (child) { if (child->isPositioned()) { child = iterator.next(); continue; } totalChildren++; child = iterator.next(); } // Iterate over the children and space them out according to the // justification level. if (totalChildren > 1) { totalChildren--; bool firstChild = true; child = iterator.first(); while (child) { if (child->isPositioned()) { child = iterator.next(); continue; } if (firstChild) { firstChild = false; child = iterator.next(); continue; } offset += remainingSpace/totalChildren; remainingSpace -= (remainingSpace/totalChildren); totalChildren--; placeChild(child, child->xPos(), child->yPos()+offset); child = iterator.next(); } } } else { if (style()->boxPack() == BCENTER) offset += remainingSpace/2; else // END offset += remainingSpace; child = iterator.first(); while (child) { if (child->isPositioned()) { child = iterator.next(); continue; } placeChild(child, child->xPos(), child->yPos()+offset); child = iterator.next(); } } } child = iterator.first(); while (child && child->isPositioned()) { child = iterator.next(); } if (child) { m_overflowTop = min(child->yPos() + child->overflowTop(false), m_overflowTop); RenderObject* lastChild = child; while ((child = iterator.next())) { if (!child->isPositioned()) lastChild = child; } m_overflowHeight = max(lastChild->yPos() + lastChild->overflowHeight(false), m_overflowHeight); } // So that the calcHeight in layoutBlock() knows to relayout positioned objects because of // a height change, we revert our height back to the intrinsic height before returning. if (heightSpecified) m_height = oldHeight; } void RenderFlexibleBox::placeChild(RenderObject* child, int x, int y) { IntRect oldRect(child->xPos(), child->yPos() , child->width(), child->height()); // Place the child. child->setPos(x, y); // If the child moved, we have to repaint it as well as any floating/positioned // descendants. An exception is if we need a layout. In this case, we know we're going to // repaint ourselves (and the child) anyway. if (!selfNeedsLayout() && child->checkForRepaintDuringLayout()) child->repaintDuringLayoutIfMoved(oldRect); } int RenderFlexibleBox::allowedChildFlex(RenderObject* child, bool expanding, unsigned int group) { if (child->isPositioned() || child->style()->boxFlex() == 0.0f || child->style()->boxFlexGroup() != group) return 0; if (expanding) { if (isHorizontal()) { // FIXME: For now just handle fixed values. int maxW = INT_MAX; int w = child->overrideWidth() - (child->borderLeft() + child->borderRight() + child->paddingLeft() + child->paddingRight()); if (!child->style()->maxWidth().isUndefined() && child->style()->maxWidth().isFixed()) maxW = child->style()->maxWidth().value(); else if (child->style()->maxWidth().type() == Intrinsic) maxW = child->maxPrefWidth(); else if (child->style()->maxWidth().type() == MinIntrinsic) maxW = child->minPrefWidth(); if (maxW == INT_MAX) return maxW; return max(0, maxW - w); } else { // FIXME: For now just handle fixed values. int maxH = INT_MAX; int h = child->overrideHeight() - (child->borderTop() + child->borderBottom() + child->paddingTop() + child->paddingBottom()); if (!child->style()->maxHeight().isUndefined() && child->style()->maxHeight().isFixed()) maxH = child->style()->maxHeight().value(); if (maxH == INT_MAX) return maxH; return max(0, maxH - h); } } // FIXME: For now just handle fixed values. if (isHorizontal()) { int minW = child->minPrefWidth(); int w = child->overrideWidth() - (child->borderLeft() + child->borderRight() + child->paddingLeft() + child->paddingRight()); if (child->style()->minWidth().isFixed()) minW = child->style()->minWidth().value(); else if (child->style()->minWidth().type() == Intrinsic) minW = child->maxPrefWidth(); else if (child->style()->minWidth().type() == MinIntrinsic) minW = child->minPrefWidth(); int allowedShrinkage = min(0, minW - w); return allowedShrinkage; } else { if (child->style()->minHeight().isFixed()) { int minH = child->style()->minHeight().value(); int h = child->overrideHeight() - (child->borderLeft() + child->borderRight() + child->paddingLeft() + child->paddingRight()); int allowedShrinkage = min(0, minH - h); return allowedShrinkage; } } return 0; } const char *RenderFlexibleBox::renderName() const { if (isFloating()) return "RenderFlexibleBox (floating)"; if (isPositioned()) return "RenderFlexibleBox (positioned)"; if (isRelPositioned()) return "RenderFlexibleBox (relative positioned)"; return "RenderFlexibleBox"; } } // namespace WebCore